Method and apparatus for facilitating setup, discovery of capabilites and interaction of electronic devices

ABSTRACT

Embodiments of the disclosure provided herein generally include a system and a method of configuring and/or controlling one or more electronic devices using a portable electronic device based on the interaction of the portable electronic device with a beacon signal generating system that is disposed at a desired location. Embodiments of the disclosure may include a system and a method of collecting and analyzing useful information received by the portable electronic device based on the receipt of a beacon signal. The portable electronic device may then perform one or more desirable functions or processes based the portable electronic device&#39;s interaction with the beacon signal generating system. Some aspects of the invention may include an apparatus, method and/or one or more computing device software applications that are configured to more easily setup, configure and/or reliably control an additional electronic device based on the interaction of the portable electronic device with the beacon signal generating system.

BACKGROUND OF THE INVENTION

Field of the Invention

Embodiments disclosed herein generally relate to methods and electronicdevices used to enable the configuration and/or control of one or moreelectronic devices using a separate electronic device.

Description of the Related Art

The popularity of portable electronics, such as smartphones, touch pads,PDAs, portable computers and portable music players, has increaseddramatically in the past decade. As the number of electronic devices andthe reliance on these electronic devices has increased, a need for thesedevices to interact and interface with each other has increased. Oneissue with the large increase in the use of electronic devices has beenthe complexity of the setup of these devices so that they can seamlesslyprovide the user with useful information and easily communicate witheach other without taking a large amount of the user's time to set up.

Video conferencing has also become more popular in recent years, thanksin large part to proliferation of high speed Internet and pricereductions in camera equipment. For example, dedicated videoconferencing locations exist where rooms and technological resources arededicated solely to the task of video conferencing. Typically, videoconferencing locations include fixed video conferencing hardware thatinclude multiple camera devices and one or more video servers that arecapable of controlling the transfer of video conferencing data betweenthe various video conferencing sites.

While video conferencing technology is rapidly improving, it remainschallenging to provide sophisticated video conferencing systems that canbe easily set up so that they can rapidly and easily interact andtransmit information electronically between multiple users at manydifferent locations. While dedicated video conferencing environmentsprovide many sophisticated features, such functionality currently comesat a substantial cost and complexity, in large part due to thesesophisticated setups requiring many different types of computer hardwarethat must interact with each other.

Therefore, there is need for methods and electronic devices that can beused to rapidly and easily setup, configure and/or control one or moreelectronic devices. There is also a need for a method and electronicdevice that will automatically and seamlessly provide desirableinformation to the user. There is also a need for a software applicationand a control method that allows a portable electronic device to easilysetup and/or one or more electronic devices, such as video conferencingsystem hardware, audio devices, computing devices, home automationdevices or other similar electronic devices.

SUMMARY OF THE INVENTION

Embodiments disclosed herein generally include a computer implementedmethod, comprising receiving a first beacon signal, wirelesslytransmitting beacon information to a back-end server via a firstcommunication link, wherein the beacon information is derived from ananalysis of the received first beacon signal. Next, receivingoperational information from the back-end server via the firstcommunication link, wherein the operational information is derived frominformation contained within the wirelessly transmitted beaconinformation, and then analyzing the received operational information.Next, wirelessly transmitting auxiliary device control information to anauxiliary electronic device, wherein the auxiliary device controlinformation comprises one or more command instructions that were derivedfrom the analysis of the received operational information, and whereinwirelessly transmitting the auxiliary device control information causesthe auxiliary electronic device to initiate a task that relates to theauxiliary electronic device's primary control function. The initiatedtask performed by the auxiliary electronic device may also includeautomatically joining a video conference using a second communicationlink that is different from the first communication link. The initiatedtask performed by the auxiliary electronic device may also include aninitiation of communication with an external video conferencing system.

Embodiments disclosed herein may further provide an electronic device,comprising a processor, a transceiver that is configured to receive abeacon signal that is wirelessly transmitted from a beacon signalgenerating device and non-volatile memory. The non-volatile memoryhaving event information stored therein and a number of instructionswhich, when executed by the processor, causes the portable electronicdevice to perform operations comprising analyzing the received beaconsignal, wirelessly transmitting beacon information to a back-end servervia a first communication link, wherein the beacon information isderived from the analysis of the beacon signal, analyzing operationalinformation wirelessly received from the back-end server via the firstcommunication link, wherein the operational information is derived frominformation contained within the wirelessly transmitted beaconinformation, wirelessly transmitting auxiliary device controlinformation to an auxiliary electronic device, wherein wirelesslytransmitting the auxiliary device control information causes theauxiliary electronic device to initiate a task that relates to theauxiliary electronic device's primary control function.

Embodiments disclosed herein may further provide an electronic device,comprising a device processor, a sensor that is configured to receive abeacon signal, and a non-volatile memory having event information storedtherein and a number of instructions which, when executed by the deviceprocessor, causes the portable electronic device to perform operationscomprising analyzing the received beacon signal, transmitting beaconinformation to a back-end server via a first communication link, whereinthe beacon information is derived from the analysis of the beaconsignal, analyzing operational information received from the back-endserver via the first communication link, wherein the operationalinformation is derived from information contained within the transmittedbeacon information, and transmitting auxiliary device controlinformation to an auxiliary electronic device. The auxiliary electronicdevice may comprise an auxiliary processor, and a non-volatile memoryhaving a number of instructions which, when executed by the auxiliaryprocessor, causes the auxiliary electronic device to perform operationscomprising initiating a task based on the received auxiliary devicecontrol information, wherein the initiated task includes an initiationof communication with an external video conferencing system.

BRIEF DESCRIPTION OF THE DRAWINGS

So that the manner in which the above recited features of the inventioncan be understood in detail, a more particular description of theinvention, briefly summarized above, may be had by reference toembodiments, some of which are illustrated in the appended drawings. Itis to be noted, however, that the appended drawings illustrate onlytypical embodiments of this invention and are therefore not to beconsidered limiting of its scope, for the invention may admit to otherequally effective embodiments.

FIG. 1 illustrates an electronic system that includes multipleelectronic devices that are interconnected using various communicationlinks, according to one embodiment of the present disclosure.

FIG. 2 illustrates multiple electronic devices that are positionedwithin a conference room environment, according to one embodiment of thepresent disclosure.

FIG. 3 illustrates a method of configuring and controlling an electronicdevice, according to one embodiment of the present disclosure.

To facilitate understanding, identical reference numerals have beenused, where possible, to designate identical elements that are common tothe figures. It is contemplated that elements disclosed in oneembodiment may be beneficially utilized on other embodiments withoutspecific recitation. The drawings referred to here should not beunderstood as being drawn to scale unless specifically noted. Also, thedrawings are often simplified and details or components omitted forclarity of presentation and explanation. The drawings and discussionserve to explain principles discussed below, where like designationsdenote like elements.

DETAILED DESCRIPTION

In the following description, numerous specific details are set forth toprovide a more thorough understanding of the present invention. However,it will be apparent to one of skill in the art that the presentinvention may be practiced without one or more of these specificdetails. In other instances, well-known features have not been describedin order to avoid obscuring the present invention.

Embodiments of the disclosure provided herein generally include a systemand a method of configuring and/or controlling one or more electronicdevices using a portable electronic device based on the interaction ofthe portable electronic device with a beacon signal generating systemthat is disposed at a desired location. Embodiments of the disclosuremay include a system and a method of collecting and analyzing usefulinformation received by the portable electronic device based on thereceipt of a beacon signal. The portable electronic device may thenperform one or more desirable functions or processes based the portableelectronic device's interaction with the beacon signal generatingsystem. Some aspects of the invention may include an apparatus, methodand/or one or more computing device software applications that areconfigured to more easily setup, configure and/or control an additionalelectronic device, or also referred to herein as an auxiliary electronicdevice, based on the interaction of the portable electronic device withthe beacon signal generating system.

In some embodiments, the apparatus and methods include a beacon signalgenerating system that can provide information to the portableelectronic device about the device the beacon signal generating systemis associated with, the environment that the beacon signal generatingsystem has been positioned within or the beacon signal generating systemitself. In one example, a first beacon signal generating system ispositioned within a conference room, and is adapted to cause thesoftware application(s) running on a portable electronic device that isbrought within the conference room to setup and/or control a conferenceroom dedicated video conferencing system (e.g., fixed video conferencingdevice) positioned within the conference room. The setup and/or controla conference room dedicated video conferencing system may be based onthe interaction of the portable electronic device with the beacon signalgenerating system. While, in this example, if the same portableelectronic device is caused to interact with a second beacon signalgenerating system, which is also positioned within the conference room,it may initiate and cause the setup and/or control of a differentauxiliary electronic device. In one example, the interaction with thesecond beacon signal generating system may initiate the control andtransmission of electronic data from an electronic whiteboard, which canthen be viewed by others that have remotely joined a video conferencedue to the initial interaction of the portable electronic device withthe first beacon generating signal system.

FIG. 1 is a schematic diagram that illustrates an electronic system 100that is disposed within an environment 101, and includes at least onebeacon signal generating system 150 that is configured to interact withan electronic device, such as a portable electronic device 105. Ingeneral, the beacon signal generating system 150 is an electronic devicethat is used in conjunction with one or more portable electronic devices105. The beacon signal generating system 150 is generally able tocommunicate with the portable electronic device 105 using acommunication link 153. In some embodiments, the communication link 153is a one-way communication path in which a transceiver 155 within thebeacon signal generating system 150 is used to transfer beaconinformation contained within a beacon signal to the portable electronicdevices 105. In some configurations, the communication link 153 is awireless communication path that is enabled by the transmission of acommunication signal from the transceiver 155, such as the transmissionof a radio signal, infrared signal, ultrasonic signal or other similarcommunication signal transfer method. Other communication signaltransfer methods that may be used include, but are not limited to,Bluetooth (BT), Bluetooth LE, Infrastructure Wireless Fidelity (WiFi),Soft Access Point (AP), WiFi-Direct, and NFC communication methods.

In some embodiments, the electronic system 100 may include the beaconsignal generating system 150 and an auxiliary electronic device that thebeacon signal generating system 150 is associated with by physicalproximity and/or by some form of communication link. In one example, asdiscussed further below, the electronic system 100 includes a beaconsignal generating system 150 that is associated with the auxiliaryelectronic device that is a video conferencing system 120. The videoconferencing system 120 may include a video conferencing controller 130and one or more video conferencing devices 110. In this example, thetransceiver 155 of beacon signal generating system 150 is in electricalcommunication with at least one component found within the videoconferencing system 120 via a wired or wireless communication link. Inone configuration, the transceiver 155 is in wired or wirelesscommunication with a video conferencing device 110 by way of acommunication link 151. The transceiver 155 may additionally oralternately be in wired or wireless communication with a transceiverwithin the video conferencing controller 130 by way of a communicationlink 152. In some embodiments, the beacon signal generating system 150is part of a component, such as the video conferencing controller 130 ora video conferencing device 110, within the auxiliary electronic device.

In general, the one or more video conferencing devices 110 may be incommunication with the video conferencing controller 130 via a wired orwireless communication link 126. The video conferencing controller 130may be in communication with one or more electrical devices that arepositioned and configured to enable the formation of a video conferencewith other external resources via one or more internet devicespositioned on the internet 145 using a communication link 121.Typically, to avoid the loss of sensitive data, the communication link121 requires information sent to or coming from the video conferencingcontroller 130 to pass through a firewall 102, which is designed toblock unauthorized incoming access while permitting outwardcommunication to one or more of the internet devices. In some cases thecommunication link 121 may support the transmission of video conferencefeeds that include audio and video streams, which require thecommunication link 121 to be formed on a high performance network thatis connected to a Local Area Network (LAN) present in each videoconference location and/or across multiple video conference locations ona Wide Area Network (WAN). The video conferencing controller 130 may beany form of conventional electronic computing device, which may includea processing system 135. The processing system 135 will typicallyinclude memory 133, input/output (I/O) devices 132, and a processor 134,which may include a central processing unit (CPU), a digital signalprocessor (DSP), and/or application-specific integrated circuits (ASIC),and other useful components. The input/output (I/O) devices 132typically includes one or more transceivers that are configured toestablish wired or wireless communication links, such as thecommunication links 123, 125 and 127, with other transceivers residingwithin other computing devices. The memory 133 may include conventionalnon-volatile memory that has one or more software applications orsoftware programs (not shown) stored therein. In some configurations,one or more of the video conferencing devices 110 may include a videocamera device that includes a CCD camera, a keyboard that is coupled tothe video conferencing controller 130, a speaker phone, speaker, orother electronic device that is useful for video conferencing. In oneexample, one or more of the video conferencing devices 110 may be anUltimate Ears Boom™ speaker, a Harmony™ universal remote control or aLogitech Connect™ or a Logitech BCC 950™ video conferencing device thatare all available from Logitech USA of Newark Calif. or Logitech EuropeS.A of Lausanne, Switzerland.

As is discussed further below, the portable electronic device 105 willgenerally use a received beacon signal to determine, by use of one ormore software applications found within the portable electronic device105, what desired activities the portable electronic device 105 willsubsequently perform. The information provided from the beacon signalgenerating system 150, or beacon information, may contain beacon signalgenerating system identification information, beacon signal generatingsystem configuration information, configuration information about theauxiliary electronic device (e.g., video conferencing system 120) thatis associated with the beacon signal generating system, informationabout the beacon signal generating system environment or other types ofdevice or physical position identifying information. The beaconinformation can be stored within memory found within the beacon signalgenerating system 150, and transferred from the beacon signal generatingsystem 150 by way of the transceiver 155. Thus, in some embodiments, theportable electronic device 105 need not contain hardware that isspecially configured to interact with the beacon signal generatingsystem 150, but only requires that the portable electronic device 105 beenabled to communicate with the beacon signal generating system 150 andhave one or more preloaded software applications running on the portableelectronic device 105 that are adapted to perform the one or moredesired activities based on the information received in beacon signal.

The beacon signal generating system 150 may be any technically feasibleelectronic device configured to interact with one or more portableelectronic devices 105. In practice, beacon signal generating system 150may be coupled to a power source (e.g., wall outlet), although a beaconsignal generating system 150 may alternately receive power from abattery. In general, the beacon signal generating system 150 maycomprise electrical components that have the capability of storing,processing and/or delivering information to another electronic device,such as the portable electronic device 105. In one embodiment, thebeacon signal generating system 150 includes a conventional electroniccomputing device. The beacon signal generating system 150 may includenon-volatile memory (not shown), a power source (not shown),input/output (I/O) devices (not shown), and a processor (not shown), assimilarly discussed above. The non-volatile memory may include variousdata files, settings and/or parameters associated with the environmentthat the beacon signal generating system 150 is positioned within,information regarding the beacon signal generating system 150 itself,and in some cases information relating to one or more users of thebeacon signal generating system 150. As noted above, I/O devices withinthe beacon signal generating system 150 may include a transceiver 155that are configured to establish one or more different types of wired orwireless communication links 153 with other transceivers residing withinother computing devices. The I/O devices may also include one or moresensors that configured to sense the interaction between a user and thebeacon signal generating system 150 or the portable electronic device105 and the beacon signal generating system 150. In some configurations,the one or more sensors may include may include motion sensing devices(e.g., accelerometers), optical sensing devices, acoustic sensingdevices, touch sensing device (e.g., capacitive sensing device) or othersimilar sensing device.

The portable electronic device 105 can be any type of portableelectronic device, such as a cell phone (e.g., smart phone), a tabletcomputing device, laptop computer, an e-book reader, a portable musicplayer, or other similar electronic device. Examples of a portableelectronic device 105 may include, but are not limited to an iPod®,iPhone®, iPad®, Android™ phone, Samsung phone, Samsung Galaxy®, Squeeze™box, Microsoft Surface®, laptop or other similar device. The portableelectronic device 105 may comprise a processing system 106 and memory107, which may contain stored data 108 and one or more softwareapplications, such as a software program 109. The processing system 106will typically include input/output (I/O) devices 106A and a processor106B, which may include a central processing unit (CPU), a digitalsignal processor (DSP), and/or application-specific integrated circuits(ASIC), and other useful components. The I/O devices 106A within theportable electronic device 105 may include a speaker 111, display device112, a touch sensing device (not shown) and/or one or more transceivers106C configured to establish a wired or wireless communication link withother transceivers residing within other computing devices, such as thecommunication links 123, 125 and 127. The I/O devices 106A within theportable electronic device 105 may also include motion sensing devices(e.g., accelerometers), magnetic field sensing devices, sound sensingdevices or other useful sensors that can be used to sense theinteraction of the portable electronic device 105 and the beacon signalgenerating system 150. The I/O devices may also include one or moretiming devices, such as a clock (not shown), that are configured toprovide time related information to the processor 106B within theprocessing system 106. The clock may be a simple IC or similarcomponent, such as a crystal oscillator. The software applications, suchas software program 109, may include software applications that areconfigured to run in the foreground or background on the portableelectronic devices 105. The software applications are used to controlone or more activities being performed by the portable electronic device105 and/or provide some useful input to the user via audio or visualmeans provided by the portable electronic devices 105.

The memory 107 may be any technically feasible type of hardware unitconfigured to store data. For example, memory 107 could include someform of non-volatile memory, such as a hard disk, a random access memory(RAM) module, a flash memory unit, or a combination of differenthardware units configured to store data. Software program 109, which isstored within the memory 107, includes program code that may be executedby processor 106B in order to perform various functionalities associatedwith the portable electronic devices 105.

The stored data 108 may include any type of information that relates tothe configuration or control of the portable electronic device, userdata, auxiliary electronic device control information (e.g., videoconferencing system control commands), beacon signal generating systemconfiguration information, useful software applications, or other usefulinformation. In some embodiments, the stored data 108 may includeinformation relating to one or more software applications or tasks beingperformed by one or more of the software applications stored with thememory 107. The stored data 108 may also include information deliveredto and/or received from the beacon signal generating system 150 atvarious times, such as information received from a prior interactionbetween the portable electronic device 105 and the beacon signalgenerating system 150. The stored data 108 may reflect various datafiles, settings and/or parameters associated with the environment and/ordesired behavior of the portable electronic device 105. The stored data108 may also include data files that contain information about the user,such as biometric data, user identification information and/or any otheruseful information. As mentioned above, software program 109 may be usedto configure the portable electronic device 105 based on stored mediadata 108. The software program 109 may also generate wireless controlsignals based on the stored data 108 and information derived from areceived beacon signal.

In some embodiments, the I/O devices 106A within the portable electronicdevice 105 may include a wireless signal strength comparison device 106Dthat is adapted to detect the signal intensity of one or more wirelesssignals that are received by a wireless transceiver 106C in the portableelectronic device 105. The signal comparison device may also include oneor more analog or digital comparison circuits (e.g., OP Amps), and atleast one feedback circuit that is able to provide the processor withinthe processing system 106 with information about the wireless signals(e.g., beacon signal) received by the beacon signal generating system150. In one example, the wireless signal strength comparison device isable to determine the relative power levels of two or more wirelesssignals that have been received from two or more beacon signalgenerating systems, such as the beacon signal generating system 150, asecond beacon signal generating system 251 (FIG. 2) and/or a thirdbeacon signal generating system 260 (FIG. 2), which is disposed in anadjacent environment 101B, as is discussed further below. Variousapplications and uses of the wireless signal strength comparison deviceare further discussed below. In some configurations, the I/O devices106A may also contain a display 112, a speaker 111, a microphone,navigation related components (e.g., gyroscope components, GPScomponents), or other desirable and useful features.

The portable electronic device 105 may also separately transmitinformation to and receive information from an internet connectedelectronic device that is also positioned within communication range ofthe beacon signal generating system 150 via an external communicationlink 123. In one configuration, the portable electronic device 105 isconfigured to communicate with an internet connected appliance or devicevia the external communication link 123 using a wireless communicationtechnique, such as a cellular phone network, WiFi network, satellitecommunication network or other useful wireless communication technique.In some embodiments, the wireless transceiver 106C is configured tocommunicate with at least one internet device, such as a back-end server143, without needing the communication signals to pass throughcommunication links that pass through the firewall 102, such ascommunication link 123 shown in FIG. 1. In some embodiments, the one ormore of the devices used to form the external communication link 123 aredifferent from the devices used to form the communication link 121 usedby the video conferencing controller 130. In one example, the externalcommunication link 123 is formed by use of a wireless communicationtechnique, such as a technique that uses a CDMA, GSM, LTE, HSPA+ orWiMax type wireless communication network, versus the communication link121 that is formed between distributed secure private domains typicallyconnected through firewall protected public access points using wiredcommunication techniques that may include fiber, cable or DSL type datatransmission methods/technologies. In another example, the externalcommunication link 123 is formed over a WiFi network that is connectedto the internet 145.

In some configurations, as is discussed further below, the internetdevices found on the internet 145 may include a back-end server 143 andone or more internet hosting devices 144, which will be discussedfurther below. In general, the back-end server 143 can be positioned atany desired location, but is configured to communicate with one or moreof the portable electronic devices (e.g., portable electronic devices105, 165) via the separate external communication link 123.

Electronic System Configuration and Processing Sequence Examples

FIG. 2 is a schematic diagram of a conferencing environment 101A thatcontains an electronic system 100 that includes a beacon signalgenerating system 150 that is configured to interact with one or moreelectronic devices, such as the portable electronic device 105. FIG. 3illustrates a process sequence 300 for configuring and/or controlling anauxiliary electronic device based on the interaction of the portableelectronic device 105 with the beacon signal generating system 150. Theprocess sequence 300 generally includes an initiation sequence 303, anoperation sequence 307 and a device control sequence 313, which are eachdiscussed below.

The process sequence 300 may start with an optional operation 302 inwhich one or more of the first software applications running on theportable electronic device 105 receive input from a user or generate aprompt that a desired event is to occur. The user input or generatedprompt may include the receipt of event information that is delivered tothe user. In the case of the prompt, the event information can beretrieved from a memory location within the memory 107. In some cases,the prompt is generated by an event software application (i.e., firstsoftware application) that is running in the foreground or background ofthe portable electronic device 105, and can access the event informationstored in memory. The event software application may be a calendarsoftware application (e.g., Microsoft Outlook, Apple Calendar, GoogleCalendar), video conference software application (e.g., Skype, GoogleHangout, Zoom Video, etc.) or other event or communication relatedsoftware application. The event information may include informationrelating to the timing of the event, Uniform Resource Locator (URL)information that is associated with the event, or event details (e.g.,location of event, attendees of the event, etc.) that are accessed by asoftware application, such as the calendar application running on theportable electronic device 105. In one example, URL information issupplied by the user to the first software application at a first timeso that an event that occurs at a later time (e.g., second time) can usethis information to access some additional event information stored onthe internet 145, such as information stored on an internet device suchas a back-end server 143. At the time the user input or prompt isgenerated by the first software application, a portion of the firstsoftware application, or a second software application that is alsorunning on the portable electronic device 105, is configured to retrievedevice configuration information that may be used to facilitate thecontrol of the auxiliary electronic device. The device configurationinformation may include information that relates to attributes of theportable electronic device 105, user specific details, preferred devicesettings used by the user and/or other useful information. The preferreddevice settings may include information relating to the setup or controlof the portable electronic device 105 or the auxiliary electronicdevice, such as a video conferencing system, a personal computer, orother useful electronic device. While the discussion below predominantlydescribes the use of the second software application (e.g., devicecontrol application) running on the portable electronic device 105 toperform one or more of the operations in the process sequence 300, thisconfiguration is not intended to limiting as to the scope of thedisclosure provided herein since the operations discussed herein couldalso be performed by portions of a single software application, such asthe first software application discussed above, that have the capabilityof providing other useful functionalities other than performing theoperations described in process sequence 300. In one example, the firstsoftware application is a conferencing software application similar toSkype, Google Hangout or Zoom Video.

The event information may also include information relating to the user,such as biometric information (e.g., facial, eye, finger, hand, DNA orsaliva information) that can be used to authenticate the user and allowthe user to pass one or more security checks found within the processsequence 300. For example, biometric information about the user can beused in the process of initiating and/or joining a video conferenceduring operation 314, which is discussed further below, to assure thatonly desired users are allowed to enter the video conference.

As noted above, most portable electronic devices used today are arepository of a large variety of information about the user, the user'sactivities, biometric information about the user and/or the user'spreferences that can be used within the process sequence 300 to morerapidly configure and desirably control the auxiliary electronic device,as will be discussed further below. The optional operation 302 can thusbe used to collect and/or receive desired user information stored withinthe portable electronic device 105, which can then be used by one ormore of the subsequent operations in the process sequence 300 to moreeasily and rapidly setup and/or control an auxiliary electronic deviceusing the collected or received user information. The presence of theuser related information stored in memory can thus reduce or prevent theneed for the user to input data that already resides on the portableelectronic device 105 when performing one or more of the processsequence steps described below.

Initiation Sequence

At operation 304, the initiation sequence 303 portion of the processsequence 300 starts with components in the portable electronic device105 receiving a beacon signal from one or more beacon signal generatingsystems 150 that are in the communication range of the portableelectronic device 105. As noted above, in some embodiments, thecommunication link 153, by which the portable electronic device 105receives the beacon signal, can be a one-way communication link thatdoesn't require the typical pairing process that is required in mostwireless communication technologies, such as Bluetooth® and others.During operation 304 a device control software application, which isrunning on the portable electronic device 105, is configured to receive,identify and/or parse the information received in the beacon signal todetect or determine the beacon information found therein. In someembodiments, the device control software application, or hereafterdevice control application, is continually running in the background ofthe portable electronic device 105, and is thus able to rapidly detectthe receipt of the beacon signal. In other embodiments, the devicecontrol application is first initiated by input from the user, orinitiated by the receipt of the event information in operation 302, sothat the device control application can then detect the receipt of thebeacon signal.

During operation the beacon signal can be received by the portableelectronic device 105 as the portable electronic device 105 is broughtinto communication range of a beacon signal generating system 150. Theportable electronic device 105 may be brought into communication rangeof a beacon signal generating system 150 as the user brings the portableelectronic device 105 into an environment that contains the beaconsignal generating system 150, such as the conferencing environment 101Ain FIG. 2. In cases where there are multiple beacon signal generatingsystems, such as beacon signal generating systems 150, 251 and 260 inFIG. 2, it may be difficult for the portable electronic device 105 todetermine which of the beacon signals is the correct one that is to beused going forward in the process sequence 300.

In cases where there are multiple beacon signal generating systems thatare within the communication range of the portable electronic device105, the device control application may not select the correct beaconsignal and beacon information that is to be used during subsequentoperations. Thus, there is a need to determine if the device controlsoftware application has received the correct beacons signal. Atoperation 306, the device control software application and electricalcomponents in the portable electronic device 105 are used toauthenticate and/or determine which of the received beacon signalinformation should be used to perform subsequent parts of the processsequence 300. During operation 306, the device control applicationdetermines which of the received beacon signals are to be used toperform a desired activity based on the interaction with the beaconsignal generating system 150. In an effort to determine which of thereceived beacon information should be used to perform subsequent partsof the process sequence 300, the device control application may utilizea physical interaction technique or one or more beacon signal analysistechniques.

In some embodiments, a physical interaction technique may includeproviding physical or non-physical (e.g., audible) input from a user tothe beacon signal generating system 150, which causes the beacon signalgenerating system 150 to deliver a beacon signal that is received by thedevice control program within a desired time. In one example, beaconsignal generating system 150 may include an accelerometer, microphone ortouch sensing element that is able to detect an input from the user. Theuser thus may provide a positive input to the beacon signal generatingsystem 150 letting it know that the user intends to interact with aspecific beacon signal generating system 150. In one example, thepositive input includes causing the portable electronic device 105 tocome into contact with a portion of the beacon signal generating system150. In some cases, the beacon signal generating system 150 may then usethe received input from the user to generate a beacon signal at adesired time. The processor 1066 in the processing system 106 (FIG. 1)of the portable electronic device 105 may initiate a timer (time T₀)based on receiving and detecting the same or similar input from the useras the beacon signal generating system received. In one example, whenthe portable electronic device 105 is caused to contact the beaconsignal generating system 150 and sensors in each device are utilized todetect the physical interaction and cause the beacon signal to be sentby electrical components in the beacon signal generating system 150 andthe timer to be started by the electronic components in the portableelectronic device 105. The timing function may be performed by one ormore timing devices disposed within the portable electronic device 105.In general, the term “timer,” as used herein, is a process that aprocessor uses to measure, monitor or determine that an amount of timehas passed. In some examples, the timer may be a count-down timer, acount-up timer or any other method that allows the processor todetermine that an amount of time has passed. Next, when the portableelectronic device 105 receives the generated beacon signal at an inputtime T₁ after the timer was initiated (time T₀), the processor 106B willcompare the difference between the input time T_(I) and time T₀ for eachof the received beacon signals to determine which of the beacon signalsis closest in time to the reception of the input at the portableelectronic device 105, and thus is the desired beacon signal to usegoing forward. Alternately, the time difference may be compared with thetime window value stored in memory, which can be used to determine ifthe received beacon signal has been received within a desired time, andthus the received beacon signal is the desired beacon signal to usegoing forward. For example, if the timing of a detected shock ormeasured acceleration (e.g., “bump”) of the portable electronic device105 is in the same time frame as a detected shock or measuredacceleration of the beacon signal generating system 150, then it islikely that the electronic device is positioned near the beacon signalgenerating system 150, and thus it is the device that the beacon signalgenerating system 150 is intended to communicate with going forward. Thedevice control application and processor 106B can thus use the timing ofthe various received beacon signals, the initiated timer and stored timewindow value type information to determine which of the received beaconsignals is the correct beacon signal to use going forward.

Alternately, in some cases the portable electronic device 105 may useone or more beacon signal analysis techniques to determine which of thereceived beacon signals is the correct beacon signal to use goingforward. In some configurations, each of the beacon signal generatingsystems may be separately and continuously delivering beacon signals atrandom or regular asynchronous intervals. In some cases, the electricalcomponents in the portable electronic device 105 are used to determinewhich of the multiple beacon signal generating systems is generating thedesired beacon signal. In some embodiments, the electrical componentsmay include the processor 106B, wireless signal strength comparisondevice 106D and memory 107. In one example, the wireless signal strengthcomparison device 106D may include components that are able to detectthe intensity of the signals received from the multiple beacon signalgenerating systems that are within communication range of the portableelectronic device 105. In one example, the components are able to detectthe power level of the received beacon signal using a received signalstrength indicator (RSSI) type technique, and determine which signal isthe strongest. In another example, the signal strength comparison device106D components are able to detect the amount of energy delivered in thebeacon signal using an optical intensity measurement detector (e.g.,photovoltaic device, photoresistor, thermopile, etc.) or a mechanicalenergy detector, such as an ultrasonic energy detector (e.g.,microphone). In general, the portable electronic device 105 can bepositioned at various distances from a beacon signal generating system150 based on the position of the user relative to the beacon signalgenerating system 150. Therefore, in some embodiments, the wirelesssignal strength comparison device 106D can be used to determine therelative distance between the beacon signal generating system 150 andthe portable electronic device 105, such that the device controlapplication within the portable electronic device 105 can determinewhich of the received beacon signals is the correct signal to use goingforward. In some embodiments, as shown in FIG. 2, the distance that theportable electronic device 105 is from the beacon signal generatingsystem 150 can be divided into two or more regions, such as an activeregion R_(A), a close region R_(C) and a far or distant region R_(F),which can be used by the device control application to decide whatactivities to perform or which beacon signal to use going forward. Thevarious signal intensity values that are associated with the regiondistances from the beacon signal generating system 150, can be stored inmemory so that the stored values (e.g., region signal intensity values)can be compared with collected signal intensity data to determine therelative distance and/or in which of the regions the portable electronicdevice 105 is positioned. The device control application can use thedefined regions to determine how the portable electronic device 105should use the received beacon information. If the portable electronicdevice 105 is in close proximity to the beacon signal generating system150, such as within the active region R_(A), the processor 106B willdetermine that the portable electronic device 105 is close to the beaconsignal generating system 150 based on its relatively high signalintensity level and thus determine that the beacon signal generatingsystem 150 is the desired beacon generating device versus the otherbeacon signal generating systems 251 or 260. In one example, the activeregion R_(A) may include a space that is between about 0.5 centimeters(cm) and 1 meter (m) from the beacon signal generating system 150, suchbetween about 1 cm and about 500 cm.

If the portable electronic device 105 is within an intermediate region(e.g., between the edge of the active region R_(A) and the edge of theclose region R_(C)), the device control application may use thisinformation to control some aspect of the subsequent process sequenceprocessing steps that is different than the case where the portableelectronic device 105 is within the active region. In one example, theportable electronic device 105 is prevented from providing controlcommands to the video conferencing system 120 if it is within the closeregion R_(C).

In some embodiments, the device control application can use the a signalintensity measurement technique to continually monitor the relativeposition of the portable electronic device 105 to the beacon signalgenerating system 150 so that the device control application can performsome desired function. In one example, one or more distances that theportable electronic device 105 is from the beacon signal generatingsystem 150 can trigger the device control application to perform adesired activity, such as extracting or pre-loading data stored inmemory (e.g., event information) when the portable electronic device 105enters the distant region R_(F) so that the portable electronic device105 can then offer a more responsive experience when it is positioned inthe active region R_(A). In another example, the device controlapplication can use the relative position information to end a videoconference as the user is leaving the environment 101A, ask the user ifthey intend to leave the video conference if a change in the relativeposition of the portable electronic device is detected (e.g., move fromthe close region R_(C) to the distant region R_(F)), or change thecurrent presenter in the meeting by detecting a change in the relativeposition of the portable electronic device to the beacon signalgenerating system 150 (e.g., move from the close region R_(C) to theactive region R_(A)). One will note that the beacon signal generatingsystem 150 need not be a stationary electronic device, and thus in somecases could be repositioned relative to the position of the portableelectronic device 105 to alter the relationship (e.g., regions R_(A),R_(C), R_(F)) of one or more the portable electronic devices 105, 165relative to the beacon signal generating system 150 in the environment101A.

In general, the wireless signal strength comparison device 106D isconfigured to deliver the derived signal intensity information to theprocessor 106B, so that the processor 106B and device controlapplication can make decisions regarding the type or part of thereceived beacon information that should be transferred in subsequentsteps. The processor in the portable electronic device 105 can use thereceived information and compare it with information stored in itsmemory to help perform one or more subsequent steps. Once the correctbeacon signal from the desired beacon signal generating system 150 isdetermined by the device control application the process sequence 300will then continue on to the operation sequence 307.

In some embodiments, where multiple beacon signal generating systems arewithin the communication range of the portable electronic device 105 andmultiple beacon signals are received, the device control application maygenerate a prompt that is displayed on the screen 112 of the portableelectronic device 105 to allow the user to decide which of the beaconsignals is the correct beacon signal that is to be used duringsubsequent operations. The user can then provide input to the portableelectronic device 105 letting it know which beacon signal is to be usedgoing forward, and the process sequence 300 can then continue onto thenext operation. The input received from the user relating to aparticular beacon signal can also be stored in memory for use insubsequent activities. The subsequent activities may include the nexttime the initiation sequence 303 and/or process sequence 300 is used bythe portable electronic device 105 so that one or more processes can becompleted in a shorter more expedient way the next time the initiationsequence and/or process sequence is performed, The collected user inputcan be stored as part of the event data stored in the memory 108 for usein subsequent operations.

During at least one of the operations performed during the initiationsequence 303 the device control application will parse the informationreceived in a beacon signal to capture the transmitted beaconinformation, which is then used in one or more of the subsequentprocessing steps. As part of the initiation sequence 303 the devicecontrol application may analyze the beacon information and/or comparethe beacon information with beacon device information stored in memoryof the portable electronic device 105 to further confirm that the beaconsignal was generated by the correct beacon signal generating system 150and/or enhance the details provided in the beacon information for use inlater process sequence steps. The stored beacon device information mayinclude unique beacon signal generating system identificationinformation, beacon signal generating system configuration information,information about the environment that the beacon signal generatingsystem is within or other information that was created from a previousinteraction of the portable electronic device 105 with the beacon signalgenerating system. In some cases, the detected beacon signal may causethe processor 106B to search for event information that is stored inmemory 107. Thus the receipt of the beacon signal can initiate thedetection of a stored event.

Operation Sequence

At operation 308, the operation sequence 307 portion of the processsequence 300 starts with components in the portable electronic device105 using the information received from the analysis of the receivedbeacon information (initiation sequence 303) and/or the received eventinformation (operation 302) to determine which of the auxiliaryelectronic device(s) the portable electronic device 105 needs tocommunicate with and/or send control commands to during the subsequentdevice control sequence 313. In some embodiments, the received beaconinformation includes configuration information, such as beacon signalgenerating system information (e.g. beacon identification information),or location information (e.g., GPS coordinates), that is used by theportable electronic device 105 to determine which of the auxiliaryelectronic device(s) the portable electronic device 105 needs tocommunicate with during this operation. In some embodiments, thereceived beacon information includes information that can be used tohelp authenticate the portable electronic device 105 to assure that thecorrect user and/or device should be able to continue forward with therest of the process sequence 300. In some cases, the received beaconinformation includes authentication codes that can be used in subsequentsteps to authenticate the portable electronic device.

During operation 308, the device control application within the portableelectronic device 105 generates one or more device communication signalsbased on the analysis of the received beacon information and/or thereceived event information. The one or more device communication signalsmay contain beacon information, event information and/or informationderived from the analysis of the beacon information and/or eventinformation. In one example, the device communication signal containsbeacon identification information. In some embodiments, the devicecommunication signal is transmitted to an external electronic device,and the device communication signal includes a URL string, which wascontained within the event information stored within the portableelectronic device 105. In some configurations, the transmitted devicecommunication signal(s) are transmitted by the portable electronicdevice 105 using the wireless transceiver 106C to the externalelectronic device, such as the back-end server 143. The one or moredevice communication signals may be sent to the back-end server 143 viaan outgoing signal sent by way of the external communication link 123.In an effort to reduce the need for user interaction to initiate thetransmission of the device communication signal and time that would berequired to transmit data securely through the firewall 102, theexternal communication link 123 may use devices and/or connection pathsdifferent from the devices and connection paths used to form thecommunication link 121. In some embodiments, the external communicationlink 123 includes a prior established wireless connection which istypically automatically formed in normal use by a portable electronicdevice, such as a CDMA, GSM, LTE, HSPA+ or WiMax type wirelesscommunication network connection that is provided to a smartphone,tablet or other similar computing device.

At operation 310, the external electronic device, which is describedhereafter as a back-end server 143, receives and processes the devicecommunication signal(s) received from the portable electronic device 105so that operational information can then be provided to the portableelectronic device 105 from the back-end server 143 via the externalcommunication link 123. The operational information will typicallyinclude information and/or commands that are used by the device controlapplication running on the portable electronic device 105 to performsome subsequent operations or tasks, such as setup, configure and/orcontrol an auxiliary electronic device. In one example, one or moresoftware applications running on a back-end server 143 are used toanalyze the received device communication signal that is then used togenerate operational information that can then be used by the portableelectronic device 105 to cause the setup and/or control a videoconference system 120. The analysis of the information received in thedevice communication signal may include the detection and analysis ofthe beacon information and/or event information contained therein. Theanalysis of the received beacon information or event information caninclude the process of detecting information relating to the timing ofthe event, URL information and/or event details (e.g., location of theevent, meeting room details) found within the device communicationsignal. In some cases, the provided beacon information is used by thesoftware applications running on a back-end server 143 to determine andretrieve information stored within the back-end server 143 regarding ascheduled event and/or information about the beacon signal generatingsystem 150 that is then used to form the operational information. In oneexample, the operational information includes specific event URLinformation that relates to a meeting that is currently being hosted oris going to be hosted by one of the internet connected appliances, suchas one of the internet hosting devices 144. The internet hosting devices144 may be in communication with an external electronic device 147 via acommunication link 148. The external electronic device 147 can be anytype of electronic device, such as an external video conferencing systemwhich can be similar to the video conference system 120 describedherein. In some embodiments, the back-end server 143 contains a libraryof stored information about regularly occurring events or one or moreelectronic system 100 components that enable the generation of theoperational information that will allow the portable electronic deviceto perform some desired subsequent task based on the receipt of theoperational information.

During the operation sequence 307, based on the receipt of devicecommunication signals, the back-end server 143 may also initiate andperform some desired additional function based on the receipt of adevice communication signal from the portable electronic device 105.Some of the desired functions may include the initiation of a videoconference, sending command signals to initiate a video conference,posting desired information on the internet or performing some otheruseful activity.

Next, at operation 312, the back-end server 143, transmits a returncommunication signal, which includes the generated operationalinformation, to the portable electronic device 105 via the externalcommunication link 123. The device control application running on theportable electronic device 105 is used to analyze the operationalinformation in the received return communication signal. The datagenerated from the analysis is then used by the device controlapplication to provide instructions or guidance regarding whichsubsequent operations or tasks that are to be performed by the portableelectronic device 105, such as setup, configure and/or reliably controlone or more additional electronic devices. In one example, theoperational information includes device identifier code informationand/or other device control information relating to the supportingelectronic device. In one example, an analysis of the receivedoperational information includes the determination that the portableelectronic device 105 is to communicate commands to a video conferencingsystem, so that a meeting can be initiated and performed by a videoconferencing system. In another example, an analysis of the receivedoperational information includes the determination that the portableelectronic device 105 is to communicate commands to a home automationdevice, such as a Smart Home™ device from Logitech, so that a user caneasily setup and/or control one or more home automation devices.

Alternately, in some embodiments of the process sequence 300, theportable electronic device 105 already has the operation informationstored within the memory 107, and thus some of the processes performedin operations 308-312 can be skipped. In this case, the receipt andanalysis of the beacon signal performed in operations 304-306 will causethe device control application to access the operational informationthat had been previously stored in the memory 107, and thus does notrequire the use of the back-end server 143 and related process sequencesteps that require its use. The operational information may have beenpreviously stored in the memory 107 when the event information wasstored in memory 107, the device control application was initiallystored within the memory 107, or received in some event informationinput activity or regular software update activity.

Device Control Sequence

At operation 314, the device control sequence 313 portion of the processsequence 300 starts with components in the portable electronic device105 using information received from the analysis of the received returncommunication signal to determine which of the auxiliary electronicdevice(s) the portable electronic device 105 needs to communicate withand/or send control commands to during the device control sequence 313.In some embodiments, operation 314 includes the transmission ofauxiliary device control information to an auxiliary electronic device,such as the video conference system 120. In general, the transmission ofthe auxiliary device control information to the auxiliary electronicdevice will cause one or more software applications running on theauxiliary electronic device to perform one or more desirable primarycontrol functions or processes based on an analysis of the receivedauxiliary device control information. The auxiliary electronic device'sprimary control function is typically performed by the softwareapplications running on the auxiliary electronic device, and may causethe auxiliary electronic device to operate in a desired way and/or toperform one or more desired tasks or activities that are in-line withits useful function. In one example, a video conferencing system'sprimary control function is to host a video conference in which videoand audio data are transferred between two or more video conferencinglocations. In another example, an electronic whiteboard's primarycontrol function can be to collect and transmit a user's input receivedon a touch screen coupled to the whiteboard to a computing device. Inyet another example, an audio device's (e.g., UE Boom™'s) primarycontrol function is to deliver a desired wirelessly received audiocontent to user. Therefore, the one or more desired tasks or activitiesperformed by the auxiliary electronic device may include starting-up oneor more software applications stored in memory within the auxiliaryelectronic device or causing the auxiliary electronic device to displayinformation contained within the auxiliary device control information.The auxiliary device control information may also provide the auxiliaryelectronic device with information that will allow the auxiliaryelectronic device to perform some desired video conferencing activities,such as initiate or enter a video conference and/or provide informationthat is displayed to the user on a display (e.g., display 140 (FIG. 1))that is connected to the auxiliary electronic device. The auxiliarydevice control information may include commands (e.g., commandinstructions) that were derived and/or generated from the analysis ofthe operational information provided in the return communication signalsent from the back-end server 143. In some embodiments, the providedcommands were specifically selected and provided from the back-endserver 143 based on the information generated from the analysis of thebeacon information received in the one or more device communicationsignals. In other embodiments, the commands and command relatedinformation are retrieved from a storage location in the memory 107 ofthe portable electronic device 105 based on the information generatedfrom the analysis of the operational information provided in the returncommunication signal. In another embodiment, the commands and commandrelated information is generated from an analysis of the received returncommunication signal and information retrieved from a storage locationin memory 107 of the portable electronic device 105.

As part of operation 314, the portable electronic device 105 may performa pairing process with the device it intends to send the auxiliarydevice control information to, such as an auxiliary electronic device. Apairing process is commonly performed by wireless portable devices toallow them to securely communicate with each other. In some cases, priorto transmitting the auxiliary device control information to theauxiliary electronic device, the auxiliary electronic device and theportable electronic device 105 are paired by use of the communicationlink formed between the wireless transceivers found in each of thedevices. The signals transferred between the auxiliary electronic deviceand the portable electronic device 105 may contain typical Bluetooth®type pairing information, such as Bluetooth device identification (ID)information, which may be stored in memory in both the transferring andreceiving devices during the pairing process. In some embodiments, thereturn communication signal sent from the back-end server 143 mayinclude specific pairing information that allows the portable electronicdevice 105 to determine exactly which auxiliary electronic device itshould communicate with within the local environment that the portableelectronic device 105 is positioned (e.g., environment 101A). In otherembodiments, the portable electronic device 105 may include stored priorpairing information that was generated or collected from prior pairingprocesses performed between the portable electronic device 105 and theauxiliary electronic device. In some embodiments, the portableelectronic device 105 may perform a scan of all wireless enabledelectronic devices that are within communication range, and select anelectronic device to pair with based on a predetermined device prioritylisting saved in the memory 107 and/or information provided in thereceived operational information. In one example, the priority listsaved in the memory is organized chronologically, such as prioritized bywhen each of the scanned devices last paired with the portableelectronic device 105. This type of priority listing can allow theelectronic device that most recently paired to the portable electronicdevice 105 to be selected over other resident electronic devices. Thepriority listing may also be organized by the most frequently useddevice, the type of device and/or by user input. In one example, aBluetooth® enabled video conference camera device may have a higherpriority than a Bluetooth® enabled tablet or other similar wirelessenabled device. The stored prior pairing information can then be used bythe portable electronic device 105 to determine the desired auxiliaryelectronic device to communicate with going forward.

In some cases during operation 314, the portable electronic device 105may initiate the communication and transmit the auxiliary device controlinformation to a specific device that was identified from informationreceived in the operational information. In the video conferencingexample, the portable electronic device 105 initiates the communicationwith video conference controller 130 via the communication link 125. Inthis example, the video conference controller 130 may then use thereceived auxiliary device control information to initiate and/or join avideo conference via the communication link 121. In some embodiments,the auxiliary device control information may also include informationabout the user (e.g., biometric information) that is collected from thereceived beacon information or event information, and thus allow theuser to pass existing security measures so that the user can join aprivate/secure video conference. In other embodiments, theauthentication data is added to the auxiliary device control informationto allow the user to pass one or more security measures so that the usercan join a private and/or secure video conference. The authenticationdata may be derived from emails, texts, user input data or other typicalcommunication techniques received by the portable electronic device 105so that a user can reliably and securely prove that they are one of theusers that are allowed to join the video conference.

Alternately, during operation 314, the portable electronic device 105may initiate the communication with an auxiliary electronic device thatis specifically configured to receive the transmitted auxiliary devicecontrol information delivered from the portable electronic device 105.In the video conferencing example, the portable electronic device 105may be specifically configured to communicate with one of the videoconferencing devices 110 via the communication link 127. In thisexample, the device control software may contain specific informationthat is stored within memory 107 about a video conferencing device 110that allows the portable electronic device 105 to rapidly and seamlesslycommunicate with the video conferencing system 120 based on the storedinformation. The notification that the specific video conferencingdevice 110 is within the video conferencing system and is the devicethat is to be communicated with may be derived from the beaconinformation and information generated from the subsequent analysesperformed by the software applications running on the back-end server143 and the device control application running on the portableelectronic device 105. In this example, the video conferencing device110 may then deliver at least a portion of the received transmittedauxiliary device control information to the video conference controller130 that then uses the received information to initiate and/or join avideo conference via the communication link 121. The process ofinitiating and/or joining a video conference may include the process ofinitiating communication with an external video conferencing device(e.g., external electronic device 147) that is in communication with theinternet hosting devices 144. The act of initiating the communicationwith an external video conferencing device will generally include thebi-directional transfer of electrical device information (e.g.,hardware, software, and capability related information) and meetingrelated information between the video conference controller 130 and theexternal video conferencing device so that a video conference can thenbe automatically or semi-automatically initiated. The provided auxiliarydevice control information (e.g., command instructions) may also causethe video conferencing system 120 to initiate and run video conferencingsoftware (e.g., Skype, Zoom Video), and/or enter a video conference thatis being hosted by video conferencing software and other externalelectronic devices. The initiated video conferencing software and/orentered video conference may cause the video conferencing system 120 todisplay video conferencing data received via the communication link 121on a conventional display 140. The specific event URL information thatrelates to the joined video conference can be provided within theauxiliary device control information.

At operation 316, one or more additional users that have separateportable electronic devices, such as a second electronic device 165, mayalso join the video conference event that was initiated by the processesdescribed within operations 303, 307 and 313. The second electronicdevice 165 can be any type of portable electronic device, as similarlydiscussed above in conjunction with the portable electronic device 105,and thus may include a cell phone, tablet computing device, laptopcomputer, e-book reader, portable music player, electronic whiteboard,touch screen display, video projector, television, home automationcomponent or other similar electronic device. The process of joining thevideo conference event can start with the second electronic device 165also receiving event information regarding the upcoming event from oneor more software applications running on the second electronic device165, as similarly discussed above. The second electronic device 165 maythen receive a beacon signal as the second electronic device 165 isbrought to a position proximate to the beacon signal generating system150 positioned within the environment 101A (FIG. 2). The process bywhich the second electronic device 165 receives and determines whichbeacon signal to use can be similar to the processes described above inconjunction with operations found within the initiation sequence 303.Using the information received from the analysis of the received beaconinformation (initiation sequence 303) and/or the received eventinformation (operation 302) the device control application running onthe second electronic device 165 will then transmit a devicecommunication signal, which may contain beacon information and eventinformation, to the back-end server 143 via the communication link 166.In general, communication link 166 may be similarly configured as thecommunication link 123 described above, and may follow a path that isdifferent from the formed communication link 121. The second electronicdevice 165 may then receive the operational information from theback-end server 143 by use of the processes described in operationsequence 307. The second electronic device 165 may then join the videoconference by use of the received operational information using thecommunication link 166. The provided operational information may causethe second electronic device 165 to enter a video conference hosted byother electronic devices and display video conferencing data receivedvia the communication link 166 on a display 167 connected to the secondelectronic device 165. The specific event URL information that relatesto the joined video conference can be provided within the operationalinformation received from the back-end server 143. The operationalinformation received by the second electronic device 165 need not be thesame information that the portable electronic device 105 received duringoperation 312, and may be specifically tailored for the secondelectronic device 165 by the back-end server 143 based on the status ofthe video conference, received device communication signal and/or thecapabilities of the second electronic device 165. The capabilities ofthe second electronic device 165 may have been determined by theback-end server 143 based on information transmitted within the devicecommunication signal previously provided by the second electronic device165. Therefore, based on the information found with the receivedoperational information, the device control application running on thesecond electronic device 165 can then automatically setup and configureapplications and hardware running on the second electronic device 165based on the initially received beacon information. The setup andconfigured second electronic device 165 can then provide a user with anyreceived information (e.g., information received from the internet 145)using the I/O devices contained within the second electronic device 165.

During operations 314-316, the transmission of the auxiliary devicecontrol information to the auxiliary electronic device may cause one ormore software applications running on the auxiliary electronic device toprovide or cause information to be provided to the users regarding anactivity related to the primary control function of the auxiliaryelectronic device. In one example, the auxiliary device controlinformation provided to a video conferencing system 120 causes the videoconferencing system 120 to display information on the display 140 thatlets the users know information about the video conference, such as thevideo conference is being initiated, the location of the conference, whois attending the video conference or other useful information.

In some cases, the one or more software applications running on theauxiliary electronic device may also provide or cause information to beprovided to the back-end server 143 which then causes softwareapplications running on the back-end server 143 to provide informationto one or more additional electronic devices, such as devices thatrelate to the primary control function of the auxiliary electronicdevice (e.g., video conferencing system 120). The additional electronicdevices may include devices that are positioned near to or are relatedto the auxiliary electronic device. The information provided by theback-end server 143 to the additional electronic device can cause theadditional electronic device to provide information to a user regardingan activity that is to be performed or is being performed by theauxiliary electronic device. In one example, the auxiliary devicecontrol information provided to a video conferencing system 120 causesthe video conferencing system 120 to transfer information to theback-end server 143. The back-end server 143 then sends generatedoperational information to a second video conferencing system that isdisposed in an adjacent conferencing environment 101B so that the secondvideo conferencing system can display information to users within theadjacent conferencing environment 101B to let them know informationabout the video conference that is to occur or is occurring in the nextconferencing environment 101A.

One will appreciate that by use of the methods described herein,multiple users that each have a second electronic device can easilyenter a video conference using the computer implemented methodsdescribed above relating to operations 303 and 307. The processes thatallow additional users to enter a video conference need not require theuse of event information or the need for the user to setup or configurethe second electronic device, since these commands and information canbe provided to the second electronic device based on the received beaconinformation and subsequently generated operational information that isderived from the information received within the initial beacon signal.

Additional Electronic Devices

At operation 318, optionally one or more additional electrical devicescan be setup and configured to interact with the auxiliary electronicdevice and/or portable electronic device 105 based on the interaction ofthe portable electronic device 105 with a second beacon signalgenerating system 251. The second beacon signal generating system 251can be similarly configured as the beacon signal generating system 150discussed above. In one configuration, the second beacon signalgenerating system 251 may be associated with a second auxiliaryelectronic device 252 as shown in FIG. 2. The second auxiliaryelectronic device 252 can be any form of electronic device, such as acell phone, tablet computing device, laptop computer, an e-book reader,a portable music player, electronic whiteboard, touch screen display,video projector, television, home automation component or other similarelectronic device that may provide some useful input directly to theuser, auxiliary electronic device and/or portable electronic device 105.In general, the processes performed during operation 318 will be similarto the processes performed during operations 303 and 307 describedabove.

During operation 318 the user may either interact with the second beaconsignal generating system 251 or cause the portable electronic device 105to interact with the second beacon signal generating system 251 in aneffort to start the beacon signal authentication process. The devicecontrol software application and electrical components in the portableelectronic device 105 will thus be used to authenticate and/or determinewhich of the subsequently received beacon signals should be used toperform the addition of the second auxiliary electronic device 252. Inan effort to determine which of the received beacon signals should beused to add the second auxiliary electronic device 252, the devicecontrol application may utilize a physical interaction technique or oneor more beacon signal analysis techniques, as similarly described above.In one example, a physical interaction technique may be used toauthenticate the beacon signal generated by the second beacon signalgenerating system 251, which cause the second beacon signal generatingsystem 251 to deliver a beacon signal that is received by the devicecontrol program within portable electronic device 105 at a desired time.In another example, as discussed above, the portable electronic device105 may use one or more beacon signal analysis techniques to determinewhich of the received beacon signals is the correct beacon signal to usegoing forward.

As similarly discussed above, in some embodiments, when multiple beaconsignal generating systems are within the communication range of theportable electronic device 105 and multiple beacon signals are received,the device control application may generate a prompt that is displayedon the screen 112 of the portable electronic device 105 to allow theuser to decide which of the beacon signals is the correct beacon signalthat is to be used during subsequent operations. The input received fromthe user relating to a particular beacon signal can then be stored inmemory for use in subsequent activities, such as the next time the newbeacon information generated by the second beacon signal generatingsystem 251 is received. In some cases, the use of the stored informationcan allow a more automated decision to be made the next time the secondbeacon signal generating system's beacon signal is desirably received.

After the portable electronic device 105 has determined which of thebeacon signals are to be used, the device control application within theportable electronic device 105 generates one or more devicecommunication signals based on the analysis of the received beaconinformation and/or the received event information. The one or moredevice communication signals may contain the new beacon informationgenerated by the second beacon signal generating system 251, eventinformation and/or information derived from the analysis of the newbeacon information and/or event information. In some embodiments, thedevice communication signal is wirelessly transmitted to the back-endserver 143 using the external communication link 123, and includes a URLlink, which was contained within the event information or beacon signalinformation stored within the portable electronic device 105.

Next, the back-end server 143 receives and processes the new devicecommunication signal(s) received from the portable electronic device 105so that a new set of operational information can then be provided to theportable electronic device 105 via the external communication link 123.The new operational information will typically include informationand/or commands that are used by the device control application runningon the portable electronic device 105 to setup, configure and/or controlthe second auxiliary electronic device 252, which, for example, may bean electronic whiteboard, video projector, touch screen or other usefulelectronic device.

The back-end server 143 then transmits a new return communicationsignal, which includes the newly generated operational information, tothe portable electronic device 105 via the external communication link123. The device control application running on the portable electronicdevice 105 is then used to analyze the new operational information. Thedata generated from the analysis is then used by the device controlapplication to provide instructions to the portable electronic device105 so that the second auxiliary electronic device can be setup,configured and/or controlled.

Using information received from the analysis of the new returncommunication signal, the portable electronic device 105 determineswhich auxiliary electronic device the portable electronic device 105needs to communicate with, and/or send control commands to, based on thereceived return communication signal. The portable electronic device 105will then transmit auxiliary device control information generated fromthe analysis of the new return communication signal to the secondauxiliary electronic device 252. The auxiliary device controlinformation provides the second auxiliary electronic device 252 withinformation that will allow the second auxiliary electronic device 252to perform some desired activity, such as initiate communication withand/or transfer of information between the second auxiliary electronicdevice 252 and the video conference system 120 or internet 145.

As similarly discussed above, in some embodiments, the transmission ofthe auxiliary device control information to the second auxiliaryelectronic device 252 may cause one or more software applicationsrunning on the second auxiliary electronic device 252 to provide orcause information to be provided to the users regarding an activityrelated to the primary control function of the second auxiliaryelectronic device 252. In one example, the auxiliary device controlinformation provided to an electronic whiteboard causes the electronicwhiteboard to transmit information to a video conferencing system 120that then displays information on the display 140 about the electronicwhiteboard or user input provided to the electronic whiteboard. Also, insome cases, the one or more software applications running on the secondauxiliary electronic device 252 may also provide or cause information tobe provided to the back-end server 143 which then causes softwareapplications running on the back-end server 143 to provide informationto one or more additional electronic devices relating to the primarycontrol function of the second auxiliary electronic device 252. In oneexample, the auxiliary device control information provided to anelectronic whiteboard causes the electronic whiteboard to transferinformation to the back-end server 143. The back-end server 143 thensends generated operational information to the video conferencing system120 so that the video conferencing system 120 can display information tousers to let them know information about the electronic whiteboard.

Therefore, by following the processes described above, one or moreadditional auxiliary electronic devices can be setup, configured andcontrolled by use of one or more beacon signal generating systems,software applications running on the portable electronic device and/orone or more software applications running on the back-end server 143. Inone example, the processes described above can be used to setup a videoconference device that can then provide additional data to an on-goingvideo conference. In one example, the user causes the portableelectronic device 105 to interact with an electronic whiteboard thatincludes a second beacon signal generating system 251 therein. Based onthe interaction of the portable electronic device 105 with the secondbeacon signal generating system 251, the portable electronic device 105is able to receive information from the back-end server 143, which isthen provided to the electronic whiteboard to cause it to wake-up andtransmit information to the video conferencing system 120 so that otherattendees at other remote locations can see any subsequent inputprovided by the user to the electronic whiteboard on their localdisplays.

One will appreciate that the device control software within the portableelectronic device 105 and methods provided herein do not require thatthe portable electronic device 105 have any prior knowledge about theauxiliary electronic device that it is intended to be setup, configuredand/or controlled, since this information can be provided to theportable electronic device 105 based on the received beacon informationand subsequently generated operational information that is derived fromthe information received within the beacon signal. Moreover, the methodsprovided herein do not require that the software applications (e.g.,video conferencing software) running on the auxiliary electronic devicehave any prior knowledge of or interaction with the portable electronicdevice 105 prior to performing parts of the device control sequence 313.Therefore, the hardware and computer implemented methods disclosedherein need not be specially designed to work with the devices that theyare to interact with during the performance of the process sequence 300,since in most cases the portable electronic device 105 need only be ableto transfer the necessary auxiliary device control information to theauxiliary electronic device. Similarly, that the device control softwarewithin the second electronic device 165 and methods provided herein donot require the second electronic device 165 have any prior knowledgeabout the event that it is intended to attend, since this informationcan be provided to the second electronic device 165 based on thereceived beacon information and subsequently generated operationalinformation. Therefore, many differently manufactured and/or configuredelectronic devices can be setup, configured and/or reliably controlledby use of the electronic system 100 described herein.

Embodiments of the disclosure may be implemented as a program productfor use with a computer system. The program(s) of the program productdefine functions of the embodiments (including the methods describedherein) and can be contained on a variety of computer-readable storagemedia. Illustrative computer-readable storage media include, but are notlimited to: (i) non-writable storage media (e.g., read-only memorydevices within a computer such as CD-ROM disks readable by a CD-ROMdrive, flash memory, ROM chips or any type of solid-state non-volatilesemiconductor memory) on which information is permanently stored; and(ii) writable storage media (e.g., floppy disks within a diskette driveor hard-disk drive or any type of solid-state random-accesssemiconductor memory) on which alterable information is stored. Thecomputer-readable storage media will include non-volatile memory thatcontains computer readable instructions, such that when the computerreadable instructions are executed by a processor, the processor willcause a computer implemented method to be performed.

The invention has been described above with reference to specificembodiments. Persons skilled in the art, however, will understand thatvarious modifications and changes may be made thereto without departingfrom the broader spirit and scope of the invention as set forth in theappended claims. The foregoing description and drawings are,accordingly, to be regarded in an illustrative rather than a restrictivesense.

The invention claimed is:
 1. A computer implemented method, comprising:receiving, at a portable electronic device, a first beacon signal;transmitting beacon information from the portable electronic device to aback-end server via a first communication link, wherein the beaconinformation is derived from an analysis of the received first beaconsignal; receiving, by the portable electronic device, operationalinformation from the back-end server via the first communication link,wherein the operational information is derived from informationcontained within the transmitted beacon information; analyzing thereceived operational information; transmitting auxiliary device controlinformation to an auxiliary electronic device, wherein the auxiliarydevice control information comprises one or more command instructionsthat were at least partially derived from the analysis of the receivedoperational information, and initiating, by the auxiliary electronicdevice, a task based on the received auxiliary device controlinformation, wherein the initiated task includes an initiation ofcommunication with an external video conferencing system.
 2. Thecomputer implemented method of claim 1, wherein the initiated taskperformed by the auxiliary electronic device further comprisesautomatically joining a video conference using a second communicationlink that is different from the first communication link.
 3. Thecomputer implemented method of claim 1, wherein the auxiliary devicecontrol information comprises a first URL that was provided in thereceived operational information, and the initiated task comprisesautomatically joining a video conference that is associated with thefirst URL.
 4. The computer implemented method of claim 1, furthercomprising: retrieving event information from non-volatile memory withinthe portable electronic device, wherein transmitting the beaconinformation to the back-end server further comprises wirelesslytransferring the beacon information and the event information to theback-end server, and wherein the operational information is derived frominformation contained in the beacon information and the eventinformation.
 5. The computer implemented method of claim 4, wherein theretrieved event information is determined from the analysis of thereceived beacon information.
 6. The computer implemented method of claim1, wherein the first communication link is a wireless communication linkformed on a CDMA, GSM, LTE, HSPA+ or WiMax communication network.
 7. Thecomputer implemented method of claim 1, further comprising: measuring asignal intensity of the first beacon signal and a second beacon signal,wherein the second beacon signal is transmitted from a beacon generatingsystem that is different from the beacon generating system thatgenerated the first beacon signal; comparing the measured signalintensity of the first beacon signal with a region signal intensityvalue; and determining that the beacon information delivered in thefirst beacon signal is the beacon information that is to be wirelesstransmitted to the back-end serve based on the comparison.
 8. Thecomputer implemented method of claim 1, wherein the received beaconsignal comprises beacon information, and wherein the beacon informationcomprises beacon signal generating system identification information,beacon signal generating system configuration information, or beaconsignal generating system environment information.
 9. The computerimplemented method of claim 1, further comprising: retrieving theauxiliary device control information from non-volatile memory within theportable electronic device before wirelessly transmitting the auxiliarydevice control information to an auxiliary electronic device, whereinthe retrieved auxiliary device control information is determined fromthe analysis of the operational information.
 10. The computerimplemented method of claim 1, wherein receiving the first beacon signalfurther comprises: detecting a physical interaction with a beacon signalgenerating system, wherein the first beacon signal is generated based onthe detected physical interaction.
 11. An electronic device, comprising:a first processor of a portable electronic device; a sensor that isconfigured to receive a beacon signal; a non-volatile memory havingevent information stored therein and a number of instructions which,when executed by the first processor, causes the portable electronicdevice to perform operations comprising: analyzing the received beaconsignal; transmitting beacon information to a back-end server via a firstcommunication link, wherein the beacon information is derived from theanalysis of the beacon signal; analyzing operational informationreceived from the back-end server via the first communication link,wherein the operational information is derived from informationcontained within the transmitted beacon information; and transmittingauxiliary device control information to an auxiliary electronic device,wherein the auxiliary electronic device comprises: a second processor;and a non-volatile memory having a number of instructions which, whenexecuted by the second processor, causes the auxiliary electronic deviceto perform operations comprising: initiating a task based on thereceived auxiliary device control information, wherein the initiatedtask includes an initiation of communication with an external videoconferencing system.
 12. The electronic device of claim 11, wherein theinitiated task performed by the auxiliary electronic device comprisesautomatically joining a video conference using a second communicationlink that is different from the first communication link.
 13. Theelectronic device of claim 11, wherein the auxiliary device controlinformation comprises a first URL that was provided in the receivedoperational information, and the initiated task comprises automaticallyjoining a video conference that is associated with the first URL. 14.The electronic device of claim 11, wherein the first communication linkis a wireless communication link formed on a CDMA, GSM, LTE, HSPA+ orWiMax communication network.
 15. The electronic device of claim 11,further comprising: a wireless signal strength comparison device,wherein the received beacon signal is a first beacon signal, and theinstructions further cause the portable electronic device to performoperations comprising: measuring a signal intensity of the first beaconsignal and a second beacon signal, wherein the second beacon signal istransmitted from a beacon generating system that is different from thebeacon generating system that generated the first beacon signal;comparing the measured signal intensity of the first beacon signal witha region signal intensity value; and determining that the beaconinformation delivered in the first beacon signal is the beaconinformation that is to be wireless transmitted to the back-end servebased on the comparison.
 16. The electronic device of claim 11, whereinthe received beacon signal comprises beacon information, and whereinbeacon information comprises beacon signal generating systemidentification information, beacon signal generating systemconfiguration information, or beacon signal generating systemenvironment information.
 17. The electronic device of claim 11, whereinthe instructions further cause the portable electronic device to performoperations comprising: retrieving event information that is stored inthe non-volatile memory, wherein the event information that is retrievedfrom the non-volatile memory is determined from the analysis of thereceived beacon information, wherein wirelessly transmitting the beaconinformation to the back-end server further comprises wirelesslytransferring the event information to the back-end server, and theoperational information is also derived from information contained inthe event information.
 18. The electronic device of claim 11, furthercomprising retrieving the auxiliary device control information from thenon-volatile memory before wirelessly transmitting the auxiliary devicecontrol information to an auxiliary electronic device, wherein theauxiliary device control information that is retrieved from thenon-volatile memory is determined from the analysis of the operationalinformation.
 19. A system for automatically configuring an electronicdevice, comprising: a first beacon generation system, comprising: afirst processor; non-volatile memory having beacon information storedtherein; and a transceiver that is configured to wirelessly transmit abeacon signal that comprises beacon information; a first portableelectronic device, comprising: a second processor; a transceiver that isconfigured to receive the beacon signal from the first beacon generationsystem; and non-volatile memory having event information stored thereinand a number of instructions which, when executed by the secondprocessor, causes the first portable electronic device to performoperations comprising: analyzing the beacon signal received from thetransceiver; transmitting beacon information to a back-end server via afirst communication link, wherein the beacon information is derived fromthe analysis of the beacon signal; analyzing operational informationreceived from the back-end server via the first communication link,wherein the operational information is at least partially derived frominformation contained within the transmitted beacon information;retrieving auxiliary device control information from the non-volatilememory based on the analysis of the received operational information;and transmitting the auxiliary device control information to anauxiliary electronic device; and the back-end server further comprising:a third processor; a transceiver that is configured to receive a devicecommunication signal from the first portable electronic device andtransmit operational information to the first portable electronicdevice; and non-volatile memory having stored therein and a number ofinstructions which, when executed by the third processor, causes theback-end server to perform operations comprising: analyzing the beaconinformation received from the first portable electronic device via thefirst communication link; and transmitting operational information tothe first portable electronic device via the first communication link,wherein the operational information is at least partially derived fromthe analysis of the received beacon information.